Adjustable indexable drill

ABSTRACT

An adjustable drill having a drill body having a longitudinal axis, and a face surface including an aperture extending into the drill body. A directional feature adjacent the aperture extends toward an edge of the drill body, and a longitudinal gullet extends from the face surface along at least a portion of the drill body. A cartridge adjacent the face surface is selectively slidable along the directional feature, and a cutting face having an insert pocket positioned adjacent the edge of the drill body in which an insert is releasably affixed.

This application is a continuation of U.S. patent application Ser. No. 12/134,766 filed Jun. 6, 2008, which claims the benefit of U.S. Provisional Patent Application Ser. No. 60/942,493 filed Jun. 7, 2007, each of which are hereby incorporated by reference.

TECHNICAL FIELD

The present invention generally relates to an indexable and adjustable size drill for producing a hole in a work piece.

BACKGROUND

Conventional twist type drills have been used for many years, generally being formed of hardened steel. Solid carbide drills provide desired strength characteristics for machining, but have various limitations. The development of drilling tools with indexable inserts overcomes some of these limitations. Indexable drills utilize cutting edges on one or more indexable, replaceable inserts. The inserts may be seated in pockets on the cutting end of a drill body. The pockets may have a shape corresponding to at least a portion of the shape of the insert. The inserts may be indexable, meaning that when the cutting edges wear in operation, the inserts may be removed or loosened from their position on the drill body, then rotated, or indexed, a pre-determined amount to enable use of additional cutting edges on the insert. At least one cutting geometry is associated with the insert, which may be on two or more index locations, such as for example an approximately triangle shaped insert having cutting geometry at three positions, an approximately square or other quadrilateral shaped insert having cutting geometry at four positions, or other suitable shapes. Inserts may be made of a material harder and/or denser than the drill body.

Indexable inserts may be capable of cutting feeds and speeds greater than a conventional twist type drill. Inserts may be carbide materials or similar materials that have a suitable hardness or may be hardened to provide a cutting edge with a hardness greater than the material being drilled. Indexable drills may be of a “one flute effective”,“two flute effective” or multi-flute effective design, where one or more inserts are provided, each having one flute effective. Twist type drills generally have two effective flutes.

Although useful for many applications, indexable drills may not be as effective for smaller holes, for example ¾ inch (about 19 millimeters) or less as the design will typically be one flute effective. In operation, a single one flute effective indexable insert may be slower than a two flute effective twist drill or a two flute effective spade insert drills. Spade type inserts have a front “blade type” drilling point and may be of carbide construction or a fine grain tool steel.

As mentioned, indexable drills may utilize one or more replaceable inserts, that are cost effective, particularly as the drill size gets larger or material gets more difficult to drill. An indexable drill may operate at a faster rotational speed, cutting greater surface area than a “spade type” drill, allowing a faster feed advancement. Another advantage of the indexable drill over a conventional spade drill, solid carbide drill, or conventional twist drill, is that the inserts are consumables. Instead of regrinding the cutting edge, the insert may be indexed to a new cutting edge and then thrown away when all the cutting edges are worn.

Indexable type drills are generally known in the art as a “roughing tool” because indexable drills may not be self-centering as in other type drilling products. Problems such as the insert flutes on an indexable not being a mirror of each other, as in spade drills or other products for example, causing non-uniform cutting forces in the operating drill. In the past, the drill may be held in the desired cutting path by a machine spindle, and the accuracy may be dependant on the rigidity of the machine and spindle, and the setup holding the part. For this reason, prior indexable drills may not be effective for drilling holes having a depth greater than 3 times the diameter. At depths greater than 3 times the diameter, the accuracy of prior art indexable drills may be reduced and the forces on the machine and machine spindle may become greater.

Indexable drills, or rough hole tooling, in the past have been made in rough hole size ranges. As the prior art drills increase in size, the difference in size from one drill to the next larger size may be about ¼ inch (about 6 millimeters) diameter or more. The end-user may have difficulty boring a hole in a single pass to a size between the prior art drill sizes. Until now, there has been little improvement in providing close drill tolerance holes in the larger drill sizes of about 1¼ inch to 5 inch (32 millimeter to 127 millimeter) and instead separate boring products are used to finish the rough hole.

Further, hole diameters between standard sizes in the past could be accommodated by special order drills. However, the lead time and expense of special order items can be high due to their low production volume, non standard size, and special engineering and sales involvement. The expense and time in obtaining these special size drills may dissuade the end user from purchasing a special drill and causing additional expense of added operations.

Also in past indexable drills, during operation, the physical cutting conditions for indexable insert drills may vary from the outside edge of the hole towards the center of the hole diameter, due to the different linear velocities of the cutting edges passing over the material. Near the center of the diameter, the linear velocity of the cutting edge may be very low. In prior indexable drills, at the low linear velocity of the center, the mechanical cutting action may be like a chisel that extrudes material. As the distance from the center increases, the linear velocity of the inserts increase, and the cutting edges may effectively shear the material. In the past, the low linear velocity at the center of the hole can cause a drill failure. To accommodate the low linear velocity at the center of the hole, drills of the prior art have attempted to utilize a center-cutting insert having a different shape, or insert material, or a special cutting edge.

Also, as the prior drills increase in size, the drill may be configured with larger sized inserts. As the insert size and shape become larger, the insert screw that retains the insert in its pocket may also change. A user having many hole sizes to create must carry a large inventory of inserts, grades of inserts, and screw sizes. The end user having holes ranging as little as 1.5 inches (38 millimeters) from the smallest to the largest, may have as many as 30 to 45 separate components to inventory.

Drills that are not balanced can cause chatter. Because indexable inserts may not be two flute effective and may not be uniform, prior indexable drills have been difficult to balance. In the past. indexable inserts have been honed or made with flat ground cutting edges to protect the edges from chatter or movement common in the prior art indexable drills. For this reason, more power was required for past drills with the honed or flat ground insert edges used in the prior art.

Indexable drills in the prior art also rely on a volume of coolant to expel the drilling chips from the hole during drilling. The chips created by the cutting action have to move back from the cutting edges and be expelled from a gullet adjacent the cutting area to keep chips from wedging in the clearance between the drill body and the cut diameter. Coolant may be pumped through the drill body, exiting on the drill end and flowing backward through pressure and momentum and pushing the chips backward up the gullet. The coolant may include a water soluble oil that may form a mist under heat and pressure of cutting. The coolant may be a health hazard to an operator when breathed and has to be contained thru filtration or other processes to reduce the airborne inhalation by machine operators.

In past indexable drills, the drill failure point may be near the center insert area. The center area may pack with chips unable to move back and over drill body structure, and out of the formed hole.

SUMMARY OF THE DISCLOSURE

The present invention relates to an adjustable drill comprising a drill body having a longitudinal axis, comprising a face surface comprising an aperture extending into the drill body; a directional feature adjacent the aperture extending toward an edge of the drill body; a longitudinal gullet extending from the face surface along at least a portion of the drill body; a cartridge adjacent the face surface and selectively slidable along the directional feature comprising: a slot along the directional feature; and a cutting face comprising an insert pocket positioned adjacent the edge of the drill body; a fastener through the slot into the aperture releasably affixing the cartridge to the drill body; and an insert releasably affixed in the insert pocket.

The adjustable drill may further comprise a second face surface comprising a second aperture extending into the drill body; a second cartridge adjacent the second face surface comprising a through hole; and a second cutting face comprising an insert pocket positioned adjacent the axis of the drill body; a fastener through the hole into the second aperture releasably affixing the cartridge to the drill body; and an insert releasably affixed in the insert pocket.

The adjustable drill may further comprise inserts of different configurations which may provide alternative cutting characteristics in conjunction with the adjustable drill.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an exploded perspective view of an adjustable indexable drill of the present disclosure with portions removed for clarity;

FIG. 2 is a front view of the drill of FIG. 1;

FIG. 3 is a partial view of cartridges and inserts of the drill of FIG. 1;

FIG. 4A is a side view of a portion of the drill of FIG. 1;

FIG. 4B is a top view of the portion shown in FIG. 4A;

FIG. 4C is a side view of the drill of FIG. 1;

FIG. 4D is a top view of the drill shown in FIG. 4C;

FIG. 5 is a top view of the drill of FIG. 1;

FIGS. 6A-6D show views of an example of a trigon insert usable in conjunction with the present disclosure;

FIGS. 7A-7D show views of an example of the drill with an alternative insert configuration;

FIGS. 8A-8D show views of an example of the drill with an alternative insert configuration; and

FIGS. 9A-9D show views of an example of the drill with an alternative insert configuration.

DETAILED DESCRIPTION OF THE DRAWINGS

The invention relates to an adjustable indexable drill, with an example presently disclosed, wherein the drill may utilize one or more insert cartridges and indexable cutting inserts. In this example, the indexable inserts drill alleviates many of the deficiencies of indexable drills previously described, and provides increased performance efficiency, reduced cost of operation, and elimination of unnecessary operations. The indexable insert drill also reduces the coolant necessary for proper operation, thereby reducing hazards to operators related to possible inhalation of such coolant materials. As will also be described, the indexable inserts drill provides for smooth, stable entry into a part being machined, thereby allowing stable operation for forming close drill tolerance holes of the desired configuration. Referring now to FIG. 1, an adjustable indexable drill 10 may comprise a drill body 12, an inboard cartridge 14, and an outboard cartridge 16. Various structures, such as cap head screws for securing the cartridges 14 and 16, and inserts described hereafter, are not shown in FIG. 1.

The drill body 12 may have an approximately cylindrical shape, and may comprise one or more longitudinal gullets 18, each gullet 18 having a leading surface 20 and a trailing surface 22. The leading surface 20 and trailing surface 22 may be about 90 degrees apart.

Alternately, the leading surface 20 and trailing surface 22 may be more or less than 90 degrees apart. An end of the drill body 12 may comprise a first face surface 26 and a second face surface 28. The longitudinal gullets 18 may extend from the face surfaces 26, 28 along at least a portion of the drill body 12. One or more insert cartridges may be used with the drill body, such as insert cartridges 14, 16, which may be affixed to the drill body 12 adjacent the face surfaces 26, 28.

The drill 10 may use multiple cutting inserts 30 for reducing chip size. The inserts may be positioned such that the cutting paths of the inserts overlap. As the drill diameter increases beyond the ability of the cutting paths to overlap each other correctly, additional inserts may be used. At least one cutting insert 30 may be affixed to each insert cartridge 14, 16. FIGS. 1 through 5 show adjustable indexable drill 10 utilizing four or more cutting inserts 30, 31, 32, 33 for illustrative purposes. It may be possible for some applications to use fewer than four inserts. In an aspect of the invention, the drill has the ability to be adjusted within a size range. The adjustability as an example as provided by allowing outboard cartridge 16 to be movable, and positioned opposite a fixed insert cartridge 14 at substantially 180°. The adjustability of the movable cartridge allows adjustment of the drilling size for accurate adjustment of the drill to a particular hole size requirement. The adjustability also allows for compensation of worn machine spindles, worn tool holders or poor setup conditions. The ability to drill a finished hole in a single operation eliminates additional boring and reaming operations, while achieving the desired finish hole size. This in turn reduces the drilling and boring inventory which is necessary for a particular application, as the drill size range eliminates the need for additional boring or reaming tools as well as reduces the need for specially built drill sizes. This also eliminates the lead time and expense of such custom-made items. As the desired hole diameter increases, additional inserts may be used, such as for example but not limited to six inserts or eight inserts. Conversely, as the desired hole diameter decreases, fewer inserts may be used, such as for example but not limited to two or three inserts. The cutting inserts 30, 31, 32, 33 comprise cutting geometry that may include cutting edges 40, 41, 42, 43, with an apex 44 formed thereon. The apex in the example shown is provided by cutting edges extending at an angle therefrom, such as about 20 degrees. The inserts may be indexable for providing one or more additional cutting edges 40′, 41′, 42′, 43′.

The inboard cartridge 14 may comprise a cutting face comprising an insert pocket positioned adjacent the axis of the drill body. The cutting insert 30 may be affixed in the insert pocket on the inboard cartridge 14 such that the cutting edge 40 is capable of cutting the centermost portion of the hole diameter.

The outboard cartridge 16 may comprise a cutting face comprising an insert pocket positioned adjacent the edge of the drill body. The cutting insert positioned for cutting the outermost portion of the hole diameter may be affixed to the insert pocket on the outboard cartridge 16. The cutting face on the outboard cartridge 16 may be about 180 degrees from the cutting face on the inboard cartridge.

The first and second face surfaces 26, 28 may be angled surfaces. As shown in FIGS. 2 and 3, the face surfaces 26, 28 may be angled at an angle A away from a perpendicular plane by a predetermined amount, such as about 2 to 5 degrees. Alternately, the face surfaces 26, 28 may be angled away from a perpendicular plane by about ½ to 10 degrees or greater. One or both face surfaces 26, 28 may be angled such that a normal vector of the face surface remains parallel to the gullet leading surface 20. Alternately, the face surfaces may have an oblique orientation. The sloping of surfaces 26 and 28 provides for smooth entry into a part surface, and facilitates stabilization of the drill during use. This also provides the function of allowing the center insert, which in this example is insert 30, and particularly the apex 44 thereof, to begin forming a track in the cutting path as the opposite or next inboard insert enters the part. The configuration allows the drill to begin to track at this point before the outer inserts begin to cut, thereby providing smooth and stable entry into the part. Angling the face surfaces 26, 28 away from the perpendicular plane positions the affixed insert cartridges 14, 16 on a corresponding angle, thereby resulting in the cutting edges 40, 41, 42, 43 to be positioned such that the inner cutting edge 40 extends outwardly to the greatest extent, with subsequent inserts being positioned away from the front of the drill. This positioning of inserts 30, 31, 32 and 33 allows each successive insert to effectively begin forming a cut, or track, before the next insert begins to cut, and so forth until each insert is engaging the part. The center insert 30 therefore begins a slight tangential loading before insert 31 begins cutting, and similarly in turn for inserts 32 and 33. The smooth entry into the part avoids wobble which may cause catastrophic rebounding in drilling with one insert effective drilling systems.

The first and second face surfaces 26, 28 may comprise a drive feature adjacent the aperture, or hole 48, extending toward an edge of the drill body, such as for example but not limited to one or more longitudinal serrations or longitudinal keyways or other geometry capable of restraining the cartridges 14, 16 when installed on the face surfaces 26, 28. As shown in FIGS. 4A and 4B, the first and second face surfaces 26, 28 may comprise a drive feature, such as serrations 50 over at least a portion of the face surfaces. As shown in this example, the serrations are 60 degree serrations, but other angle serrations may be suitable as desired. Alternatively, a drive key type of arrangement could be used or any other suitable drive configuration. The inboard cartridge 14 and the outboard cartridge 16 may have corresponding geometry for engaging the restraining geometry on the face surfaces 26, 28, such as corresponding serrations, drive keyways or other geometry capable of restraining the cartridges 14, 16 when installed on the face surfaces 26, 28 as seen in FIGS. 4C and 4D. The drill body 12 may have apertures extending into the drill body, or holes 48, for receiving screws or fasteners, such as cap head screws (not shown) for affixing the cartridges 14, 16. The cartridges 14, 16 may be releasably affixed to the drill body 12 by fasteners such as for example but not limited to screws or other fasteners. The fasteners may be socket head cap screws. This design allows the cartridges 14 and 16 to be selectively replaced, to allow effective replacement of the front cutting surfaces associated with the drill assembly, in a simple and effective manner. The design of the present invention also allows the distance from the drill body transition to the cutting insert pockets 34 to be kept short, to reduce any bending moments on the inserts. The distance from the end of the drill body 12 to the cutting edge 40 may be in a range of about ½ to 1 inch (about 12 to 25 millimeters). Alternately, the distance from the end of the drill body 12 to the cutting edge 40 may be in a range of about ¾ to 2 inch (about 19 to 51 millimeters). Supporting the cartridges close to the cutting edge tends to reduce forces in the drill 10.

The inboard cartridge 14 and the outboard cartridge 16 may have apertures through the cartridges for affixing the cartridges to the drill body. As shown in FIGS. 4B and 5, an aperture 52 through the inboard cartridge 14 and aperture 54 through the outboard cartridge 16 may comprise a counter-bore to provide clearance for a screw head or other fastener feature. For example, cap head screws (not shown) may be used to fasten the cartridges 14 and 16 via apertures 52 and 54, and in association with apertures formed on the face sides 26 an 28. The position of mounting apertures 48, 52, 54 may allow a user to install the cartridges from the face end of the drill. By positioning the mounting apertures 48, 52, 54 toward the face end of the drill, a user may be able to remove the cartridges while the drill is positioned in a machine spindle, which may save time for the user.

Alternately, one or more of the cartridges may be integrated into the drill body (not shown).

The gullet 18 may have a shape that opens the gullet to allow less impedance to the chip flow. The leading surface 20 of the gullet may be approximately flat. The trailing surface 22 may be an elliptical concave surface as shown in FIG. 1. The elliptical trailing surface 22 may reduce the amount of coolant pressure and flow required to evacuate the chip rearward and away from the cut. Reducing coolant pressure and volume may reduce the amount of misting of the coolant to be contained by filtration or other processes. For some materials, the indexable drill 10 may enable dry cutting.

The cutting inserts 30, 31, 32, 33 may be positioned in pockets or cavities cut into the inboard and outboard cartridges 14, 16. The pockets may be shaped to correspond to at least a portion of the shape of the inserts. Further, the pockets may be shaped such that the inserts are angled with respect to a surface of the cartridges. The rotation of the insert pocket outward of the 20 degree apex may reduce “push off” of the center insert caused by the lower linear velocity of the insert near the centerline of the hole, such as by 1.5 to 2.75 degrees from perpendicular for example.

The drill 10 may be adjustable to different diameters within a size range. The outboard cartridge 16 may be a movable cartridge adjacent the face surface and selectively slidable along the directional feature. As shown in FIGS. 4B and 5A, the aperture 54 may be a slot along the direction of serrations 50. The slot may be sized to allow translation of the outboard cartridge 16 about 1/16 to ½ inch (about 1 to 12 millimeter) or more for larger drill bodies 12. Alternately, the slot may be sized to allow translation of the outboard cartridge 16 about ⅛ to ¼ inch (about 2 to 6 millimeters). Other amounts of translation are contemplated as may be desired for various applications. In operation, to adjust the outboard cartridge 16, the fastener affixing the cartridge to the drill body may be loosened, allowing the cartridge to slide or translate the length of the slot. When the cartridge is positioned as desired, the fastener may be re-tightened to affix the cartridge to the drill body.

An adjustment to the drilling diameter may allow the end user to adjust the drill to accommodate various hole diameters. Adjustability allows for the user to compensate for worn machine spindles, worn tool holders, or poor setup conditions. The drill adjustment may also reduce costly secondary operations such as boring or reaming after drilling. The adjustability feature may also reduce the amount of drilling and boring tool inventory maintained by a manufacturing facility. Further, the adjustability feature may also reduce the need for expensive special order drill sizes. As an example, a family of drill systems may be provided in overlapping drill sizes, such as with a range of approximately 0.200 inches on diameter to enable the hole drilling of a virtually infinite amount of hole sizes, to thereby allow desired finish hole sizes to be produced.

The adjustable indexable drill 10 may use multiple inserts that may distribute cutting forces over a cut width, with a slightly thicker insert. The insert edge has a more free cutting rake or inclination that is allowed by the stability of the drill. By eliminating honed edges and strengthening the cutting area, less power may be used to drill the hole, providing a savings to the user. Smaller insert sizes may also use less material in the cutting tool insert. The one or more cutting inserts may be fastened to the at least one cartridge, such as cartridges 14 and 16, in any suitable manner, such as by cap head screws (not shown) or the like.

Turning to FIG. 6, there is shown in FIGS. 6A-6D in more detail a trigon type of insert 60 that may be used in the drill according to the examples of the invention. In FIG. 6, the trigon insert 60 includes three sides 62 having first and second portions 64 and 66, with portion 64 forming a cutting edge 68 and relief surfaces at about 7 and 15 degrees respectively, as shown in the cross-sectional view. A central aperture 69 for a fastening member is provided. As seen in FIG. 6B, the sides 62 may be angled at a desired angle relative to an adjacent side 62, such as oriented at angles A of about 80 degrees plus/minus 0.5 degrees, and each include two sections 70 and 72 angled at a desired angle B, such as oriented at an exterior included angle of about 160 degrees as shown in this example. The cutting edges 68 are provided on each surface 62, extending from the axial center of the side 62. The cutting edges 68 are substantially tangent to inscribed circle C from dead center of insert 60. The diameter of circle C may be of a desired dimension D, such as 7.938 plus or minus 0.05 mm as an example. A radius F may be provided between sides 62, such as a radius of 0.787 mm for example. The cross section shown in FIG. 6C is taken along line 6C-6C of FIG. 6B. As shown in this Fig., the aperture 69 has a desired configuration for mating with a attachment screw, with an outboard dimension G, such as a dimension of 4.93 plus or minus 0.07 mm, and an inboard dimension H, such as a dimension of 3.23 plus or minus 0.07 mm. A radius I may be formed at a midpoint of aperture 69, such as a radius of 2.362 for example. At the outboard side, the aperture 69 may have a portion 65 having a counterbore J of 0.51 plus or minus 0.07 mm for example. A radius may be formed between portion 65 and the adjacent portion of the aperture 69, such as a radius of 0.203 for example. The surfaces 64 and 66 may be formed at desired angles to the cutting edge 68, such as at a first primary clearance angle K for surface 64, such as 7 degrees, and a secondary clearance angle L for surface 66, such as 15 degrees. If desired, only a primary clearance surface may be used. In this example, the dimensions of the primary and secondary clearance surfaces 64 and 66 may be selected as desired. The insert 60 may have a desired thickness N, such as 3.96 plus or minus 0.02 mm, with surface 64 having a dimension O, such as 1.905 mm. In this and other examples, the inserts are designed to have a larger thickness dimension than ISO standard thicknesses, to provide strength and durability. For example, the thickness is at least 0.4 mm greater than the international standard thickness. The enlarged partial section of FIG. 6D, taken at section 6D of FIG. 6C, shows the detail of the cutting edge portion 68 and chip breaker surface 63. The cutting edges 68 may include a plurality of cutting components, which cooperate together to provide the desired cutting surface for the material and/or drilling application. In general, the insert 60 is designed to cut when rotationally driven in conjunction with holder in a predetermined direction. The insert aperture 69 cooperates with an aperture in the inboard cartridge 14 or the outboard cartridge 16 to secure insert 60 within a pocket on the cartridges 14 and 16 for example. The aperture 69 may be formed with countersunk portions formed as a bearing surface adapted to be engaged by a corresponding tapered or like surface on a fastening member such as a screw or the like, and the aperture 69 and corresponding aperture in a cartridge 14 or 16 may be offset, such that upon securing insert 60 within a pocket, the insert 60 will be forced against seating surfaces in the pocket. Adjacent the cutting edges 68 of each side 62, the cutting lip or chip breaker surfaces 63 are formed as seen in FIG. 6D, to form desired chip forming and breaking surfaces in conjunction with the cutting edge 68. Other aspects of a particular type of trigon insert are noted in these Figs, but it should also be understood that other trigon or trochoid inserts may be formed differently so as to be suitable for use for various applications if desired. In this example, the particular trigon insert 60 has an isometric configuration and has a predetermined included angle which may vary in accordance with the size of the drilling tool if desired. The insert 60 also has primary and secondary clearance surfaces, but it should also be understood that other configurations are contemplated.

In FIGS. 7A-7D, a diamond shaped insert 80 is shown as an example of an insert usable in the drilling system. The diamond shaped insert 80 is seen to have four sides with each having a cutting edge 81 associated therewith. In this example of a diamond shaped insert 80, as seen in FIG. 7B, the cutting edges 81 may be formed to be tangent to an inscribed circle 82, such as having a ⅜ inch diameter. The cutting edges 81 are also formed at a predetermined angle 84 to one another, such as an angle of 80 degrees. As seen in FIG. 7C, showing a cross section taken along line 7C-7C of FIG. 7B, a primary clearance surface 86 is formed behind the cutting edges 81, and the insert has a thickness 87, such as about 0.1563 mm. An enlarged detail of a cutting edge 81 is shown in FIG. 7D, showing a chip breaking surface 88 formed adjacent the cutting edge 81.

In FIGS. 8A-8D, a quadron shaped insert 90 is shown as an example of an insert usable in the drilling system. The quadron shaped insert 90 is seen to have four sides with each having several cutting edges 91 associated therewith. In this example, the quadroon insert 90 is formed to have a rhombus-type shape. As seen in FIG. 8B, the quadron insert 90 may have a plurality of cutting edges formed to be tangent to an inscribed circle, such as having a diameter 92 of 0.3750 for example. The cutting edges 91 may be formed to be positioned at a desired location relative to the centerline of each side of the quadron insert 90, such as positioned at an angle 94, for example at an angle of 80 degrees, to one another, such that the insert cutting edges 91 are skewed from the centerline of the insert 90 when positioned in a corresponding pocket 34 in a cartridge 14 or 16. Each side of the quadron insert 90 may be configured to have the cutting edges 91 formed at an included angle 96 to one another, such as at an angle of 160 degrees for example. As shown in FIG. 8C, there may be provided a primary clearance surface 100 adjacent each cutting edge 91, formed at an angle 102 such as an angle of 8 degrees for example. The attachment hole 104 may be configured to allow attachment as desired. As seen in FIG. 8D, there may be a chip breaking surface 114 formed adjacent each cutting edge 91.

In FIGS. 9A-9D, a square shaped insert 130 is shown as an example of an insert usable in the drilling system. The square shaped insert 130 is seen to have four sides with each having a cutting edge 132 associated therewith. As seen in FIG. 9B, the cutting edges 132 may be formed tangent to an inscribed circle 134 having a predetermined diameter, such as a ⅜ inch diameter for example. The cutting edges are formed at an angle 136, which for a square insert 130 is 90 degrees. The insert 130 may have a side dimension 138, such as 0.3750 for example. As shown in FIG. 9C, there is a primary relief surface 140 formed at a predetermined angle, such as an angle of 8 degrees, with details of the attachment hole similar to the quadron insert mentioned previously for example. As seen in FIG. 9D, there may be a chip breaking surface 144 formed adjacent each cutting edge 132.

The types of inserts shown in FIGS. 6-9 are examples of types which may be suitably used, but other configurations are also contemplated, while providing indexability between the cartridges in which they are positioned.

While the invention has been illustrated and described in detail in the foregoing drawings and description, the same is to be considered as illustrative and not restrictive in character, it being understood that only illustrative embodiments thereof have been shown and described, and that all changes and modifications that come within the spirit of the invention described by the following claims are desired to be protected. Additional features of the invention will become apparent to those skilled in the art upon consideration of the description. Modifications may be made without departing from the spirit and scope of the invention. 

What is claimed is:
 1. An adjustable drill comprising: a drill body having a rotational axis, comprising: at least two top face surfaces comprising a directional feature formed in association with the at least two top face surfaces; at least one cartridge adjacent each top face surface and having a mating surface to mate with the directional feature, with at least one of the cartridges being slidable along the directional feature and comprising: a slot having an axis along the directional feature; and a cutting face comprising at least one insert pocket positioned adjacent the top edge of the cartridge; a fastening system for releasably affixing the cartridges to the two top face surfaces; and at least one cutting insert releasably affixed in the insert pocket, wherein the at least one insert in each of the at least two cartridges form an entire hole in a workpiece, and the at least one slidable cartridge is infinitely adjustable to adjust the diameter of the hole.
 2. The adjustable drill according to claim 1, wherein the top face surfaces are angled obliquely away from a plane perpendicular to the axis.
 3. The adjustable drill according to claim 1, wherein the directional feature is at least one longitudinal serration.
 4. The adjustable drill according to claim 3, wherein a plurality of serrations are provided.
 5. The adjustable drill according to claim 4, the serrations are about 60 degrees.
 6. The adjustable drill according to claim 1, wherein the directional feature is at least one longitudinal keyway.
 7. The adjustable drill according to claim 1 further comprising: at least two insert pockets in each cartridge having at least one insert releasably affixed in each insert pocket.
 8. The adjustable drill according to claim 1, wherein the directional feature on the top face surfaces drives the cartridge mounted thereon.
 9. The adjustable drill according to claim 1, the second cartridge cutting face being about 180 degrees from the first cartridge cutting face.
 10. The adjustable drill according to claim 1, wherein the at least one insert includes first and second clearance surfaces adjacent the cutting edges of the insert.
 11. An adjustable drill comprising: a drill body having a rotational axis, comprising: at least two top face surfaces comprising a drive feature formed in association with the at least two top face surfaces; at least one cartridge adjacent each top face surface and having a mating surface to mate with the drive feature and to be driven with the drill body, with at least one of the cartridges being slidable along the top face surface and having a cutting face comprising at least one insert pocket positioned adjacent the top edge of the cartridge; a fastening system for releasably affixing the cartridges to the two top face surfaces; and at least one cutting insert releasably affixed in the insert pocket, wherein the at least one insert in each of the at least two cartridges form an entire hole in a workpiece, and the at least one slidable cartridge is infinitely adjustable to adjust the diameter of the hole.
 12. The adjustable drill of claim 11, wherein the distance from the end of the drill body to the cutting edge of the at least one insert is in a range of about ½ to 2 inches.
 13. The adjustable drill of claim 11, wherein the at least one insert pocket is rotated insert pocket outward from the rotational axis.
 14. The adjustable drill of claim 11, wherein the at least one insert pocket is rotated about 1.5 to 2.75 degrees from the rotational axis.
 15. The adjustable drill of claim 14, wherein the at least one insert is indexable.
 16. The adjustable drill of claim 15, further comprising at least one gullet having a leading surface formed in the drill body, and wherein at least one face surface is angled such that a normal vector of the face surface remains parallel to the gullet leading surface.
 17. The adjustable drill of claim 16, comprising a plurality of inserts including at least one inboard and outboard insert, wherein the at least one inboard insert begins forming a track in the workpiece before the at least one outboard insert begins to enter the workpiece.
 18. The adjustable drill according to claim 11, wherein the top face surfaces are angled obliquely away from a plane perpendicular to the axis.
 19. The adjustable drill according to claim 12, wherein the drive feature is a plurality of longitudinal serrations, and wherein the serrations are about 60 degrees.
 20. The adjustable drill according to claim 13, wherein the drive feature is at least one longitudinal keyway formed in each face surface. 